河道砂岩储层增强历史匹配综合建模框架

IF 2.6 Q3 ENERGY & FUELS
Hung Vo Thanh, Yuichi Sugai
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引用次数: 27

摘要

岩相和岩石物性建模是油气勘探和生产初期具有挑战性的过程。然而,有限的井数据和岩心数据是传统建模过程面临的主要问题。将人工神经网络(ANN)、序贯高斯模拟(SGS)、协同克里格(Co-kriging)和基于对象的建模(OBM)相结合,作为河道砂岩储层岩相和岩石物性建模的增强框架。在OBM中,在岩相模型中形成了多条河道。该模型反映了河道储层的全部特征。模型以河道、裂缝、河堤为沉积相,背景为页岩。通过多种地质认识和交叉验证,选择了最合适的岩相分布。利用序贯高斯模拟方法对孔隙度和渗透率进行了交叉验证。此后,继续使用人工神经网络进行建模过程。利用人工神经网络训练各种地震属性和测井数据,预测岩石物性(主要是孔隙度和渗透率)。采用协同克里格算法,将人工神经网络预测模型与OBM模拟岩相模型相结合,保留了地质系统的河流特征。为了实现完整的油田历史匹配,最终的地质模型被升级为动态历史匹配的输入数据。从试井和生产历史中获得的测量数据和模拟井底压力之间的匹配非常好,几乎是完美的。结果表明,人工神经网络和其他地质统计方法的有效集成工作流程是实现良好历史匹配的必要条件。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Integrated modelling framework for enhancement history matching in fluvial channel sandstone reservoirs

Modelling lithofacies and petrophysical properties are the challenging processes at the beginning of exploration and production of hydrocarbon reservoirs. However, the limited amount of well data and core data are the main issues facing conventional modelling processes. In this study, Artificial Neural Network (ANN), Sequential Gaussian Simulation (SGS), Co-kriging and object-based modelling (OBM) were integrated as the enhancement framework for lithofacies and petrophysical properties modelling in the fluvial channel sandstone reservoir.

In the OBM, multiple fluvial channels were generated in the lithofacies model. The result of this model represented all the characteristic of the fluvial channel reservoir. The model was then distributed with channels, crevasse, and leeves depositional facies with background shale. Multiple geological realizations were made and cross-validation to select the most suitable lithofacies distribution. This model was cross-validated by modelling the porosity and permeability properties using Sequential Gaussian Simulation.

Thereafter, the modelling process continued with Artificial Neural Network. Petrophysical properties (mainly porosity and permeability) were predicted by training various seismic attributes and well log data using the ANN. Applying the co-kriging algorithm, the predicted ANN model was integrated with OBM simulated lithofacies model to preserve the fluvial features of the geological system. To achieve full field history matching, the final geological model was upscaled to serve as input data in dynamic history matching.

An excellent and nearly perfect history matching with a least mismatch was obtained between the measurement and simulated bottom hole pressure from well test and production history. The results indicated that an efficient integrated workflow of ANN and other geostatistical approaches are imperative to attaining an excellent history matching.

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